ROBOTICS, BRAIN AND COGNITIVE SCIENCES – PROF. GIULIO SANDINI

STREAM 1: Manual and Postural Action

This theme of research is devoted to study in humans and implement in the iCub the execution and understanding of goal-directed actions. Considering that RBCS robotic platform is a full humanoid robot, it will be possible to study complex actions in terms of their specificity as well as commonalities. Specific target of our studies will be manipulative actions (mono- and bi-manual), whole body coordination (e.g. reaching outside the peripersonal space, crawling etc.). In the iCub this includes activities devoted to the study of learning methods and procedures for skill acquisition and the general topic of the control of movement as for example using force and impedance control, modularity and whole body movements. The goals are in terms of implementing force control and dynamics compensation/shaping, whole body movements (crawling, balancing) and inverse kinematics schemas.

Robots are still unable to perform dexterous tasks such as buttoning a shirt or turning a coin with the fingertips. Considerable research on the way humans perform and learn such tasks is needed to provide the basic science necessary to endow humanoid robots with such capabilities.

Recently, a number of research activities in the field of robotics have been directed towards the development of complex software frameworks. The goal of these activities is to provide development tools, computational models, and functional libraries, which allow engineers and developers of complex robotic systems to significantly reduce the development time and effort ([1] [2]). The present project proposal aims at developing a novel software architecture for describing robot whole-body dynamics integrating information from several sensors (e.g. providing force, torque, touch, acceleration and position [5]). Implementations of such architectures already exist (see [3-5] just to mention a few). The peculiarity of the proposed project is the idea of creating a common dynamic engine to be reused in different contexts. Such a dynamic layer could potentially serve a number of complementary software tools and applications: simulations (i.e. prediction of future events), motor control and planning, motor adaptation and estimation. The idea is to create a common dynamic engine for simulation and real-time exploitation, estimation and prediction, perception and motor control. Such a software component will be a core module of the iCub software architecture [1] and will significantly improve the capabilities of the current dynamic engine adopted in the iCub [2].

[2] http://www.best-of-robotics.org

[3] OROCOS (http://www.orocos.org

[4] http://stanford-wbc.sourceforge.net/

[5] Fumagalli, M., Ivaldi, S., Randazzo, M., Natale, L., Metta, G., Sandini, G., & Nori, F. (2012). Force feedback exploiting tactile and proximal force/torque sensing. Theory and implementation on the humanoid robot iCub. Autonomous Robots, In press.

Theme 1.3: iCub whole-body motion coordination exploiting distributed force and tactile sensing

Tutor: Francesco Nori

N. of available positions: 1

The goal of this project is to enhance the iCub capabilities in terms of physical interaction and physical mobility. Traditional industrial applications involve structured interaction and extremely limited mobility (i.e. robots fixed on the ground). Foreseen robot applications demand for (1) enhanced autonomy (i.e. physical mobility) and (2) flexible interaction. Remarkably, the two problems cannot be treated separately since interaction forces might compromise stability, especially in the case of free-floating robots (i.e. no longer fixed to the ground). This project proposes to develop an integrated whole-body controller capable of integrating focal (e.g. goal directed reaching) and postural (i.e. balancing) tasks. Postural control will include multiple contacts (e.g. support on a handrail), possibly exploring the possibility of exploiting non-rigid contacts (e.g. balancing on a soft carpet). To demonstrate the project outcomes, theoretical results will be implemented on the iCub robot platform (http://icub.org). The iCub represents the current state-of-the-art in European technology of cognitive humanoid robotics, and is one of the few `multi-degree-of-freedom’ robotic platforms eligible for validating the project’s objectives. Required iCub peculiarities are whole-body mobility and whole-body distributed sensors. Specifically, the project will leverage state-of-the-art technology in force and tactile sensing, a fundamental prerequisite for performing whole-body contact tasks in autonomous, unstructured and hard-to-predict contexts. In particular, the iCub has been recently enhanced with a whole-body distributed artificial skin (outcome of the ROBOSKIN FP7-ICT-231500 European project) and a whole-body force/compliance control (outcome of the CHRIS FP7-ICT-215805 European project).

In the field of robotics there has been a growing interest in simultaneous control of movements and interaction. When a perfect model of the environment is available, classical hybrid force/position controllers can be adopted [1] to achieve simultaneous control of posture and interaction. In realistic scenarios however, we need to take into account two major issues: (1) models should be continuously and iteratively updated in response to a continuously evolving environment; (2) models are always affected by errors which should be compensated with appropriate control actions (when they prevent the task achievement). This project aims at building a hybrid force/position controller constituted by two principal components: (1) an adaptive part which continuously estimates a model of the controlled system and of the surrounding environment (2) a motion planner, which takes into account uncertainties in the acquired model. Theoretical results will be validated on a prototype robot arm equipped with state-of-the-art passive variable stiffness actuators [2]. Possible extensions include applications on the iCub humanoid robot (http:/www.icub.org).

The motor system shows some interesting parallels with language organization. The possible commonalities between Action and Language are based on neurophysiological, neuroanatomical and neuroimaging data. In fact, the motor system may have furnished the basic computational capabilities for the emergence of language syntax. Generally speaking, processing hierarchies is a key ability in humans, allowing individuals to perform a variety of complex behaviors, including language. A common feature of all these behaviors is that they can be considered as structured sequences following syntactic-like rules. Regarding its crucial role in linguistic syntax, the historically well‐known but functionally still mysterious Broca’s area, located in the left frontal cortex of the human brain, has been considered as a serious candidate to support this syntactic function in a domain‐general fashion. Accordingly, it has been considered a “supramodal syntactic processor”. Despite a constantly growing number of studies that try to gain further insight to this issue, strong evidence remains sporadic.

The successful candidate will run experiments using Transcranial Magnetic Stimulation (TMS) and Electroencephalography (EEG) techniques to reveal the implications of Broca’s area and the motor system in general, in various syntax‐processing tasks in the action domain. Thus, the general goal of this project will be to investigate the role played by Broca’s area in motor cognition.

Requirements: The successful candidate will have an advanced cognitive neuroscience background and basic programming skills (Matlab preferred) as well as basic experience with TMS and/or EEG.

For further details concerning the research project, please contact: alessandro.dausilio@iit.it
Theme 1.8: Development of sensori-motor skills and sensory integration within the haptic modality

Tutor: Gabriel Baud-Bovy and Monica Gori

N. of available positions: 1

During haptic exploration we are able to reconstruct the shape of objects that we are manipulating by integrating tactile, proprioceptive and motor information. How this integration occurs, how the mental representation of objects emerges and how the motor pattern of exploration influences this perception is still debated. A still open question is how these exploratory patterns and how perceptual abilities emerge during the development and which motor skills are necessary for this development. Is therefore interesting to study how the relation between motor skills and perceptual object pattern identification evolve in order to build a global object representation in the mind. To address this point in our laboratory we are studying how haptic cue information is integrated during development and the link between the emergence of motor pattern and the related perceptual object identification. The PhD student will be involved in designing and performing behavioral experiments in toddlers, children and adults. Both motor and perceptual abilities of the subject will be evaluated by analyzing movement indexes (motor synergies, reaction times, accuracy) and interaction parameters by sensorizing the objects. The information obtained will be then implemented in our robots and will be used to develop rehabilitation programs in people with sensory and motor disabilities.

This research project is aimed at better understanding the interaction between movement planning and decision-making. Decision and motivational processes that drive our interaction with humans and non living objects range from those that are largely externally driven (e.g., stop when the light is red) to internally driven (e.g., fatigue or physiological state). Experimental evidence indicates that the topology of saccadic eye movements, classically associated to movement planning, is affected by the task expected rewards. This indicates that the planning aspects of eye movements are susceptible to the value associated to that action. We recently developed an experimental paradigm called “reaching-to-a-bar paradigm” (Berret et al. 2011a, b) that confronts the subject to a decision making process because of the lack of a particular target to reach on the bar. Decision making processes will be approached using this paradigm for which mainly subjective rewards contribute to the endpoint selection. Specifically movement planning could determine the gaze direction that in turn can predict the cost functions implemented by the brain.

The candidate will investigate the above questions using standard experimental designs (3D motion capture systems, eye-tracker, psychophysics…) and/or mathematical models (e.g. optimal control, decision theory…).

Candidates with a background in computational sciences (bio-engineering, physics or mathematics) or experimental sciences (neurosciences, psychology) are desired. The candidate must be motivated and must show a strong interest for both building model and designing experiments.